Server room managing air conditioning system

ABSTRACT

In accordance with embodiments, a server room managing air conditioning system includes: a first coil; a second coil; and an air supply fan. The first coil adjusts returned air of a server room to a predetermined temperature value lower than a supplied air temperature target value and dehumidifies the returned air. The second coil adjusts the returned air of the server room to a predetermined temperature value higher than the supplied air temperature target value so that the supplied air temperature target value and a supplied air humidity target value can be achieved when the returned air is mixed with air adjusted by the first coil. The air supply fan mixes the returned air and supplies the mixed returned air as the supplied air to the server room.

CROSS-REFERENCE TO RELATED APPLICATION

This application is a Continuation of PCT Application No.PCT/JP2012/50909, filed on Jan. 18, 2012, and claims the priority ofJapanese Patent Application No. 2011-056562, filed on Mar. 15, 2011, thecontent of both of which is incorporated herein by reference.

TECHNICAL FIELD

Embodiments of the present invention relate to a server room managingair conditioning system.

BACKGROUND ART

In general, in a server room managing air conditioning controlapparatus, there is performed air conditioning by temperature/humidityadjustment based on conditions where a mechanism similar to thatoriented for a general building is provided, and airflow on theperipheries of information instruments is optimized, and so on, wherebyachievement of energy saving enhancement is widely performed.

In recent years, an information amount has been increased bypopularization of the Internet, and the like, whereby data centers, eachof which is provided with such a server room, have been built more, andenhancement of energy saving performance of these facilities has beenwidely regarded as a subject.

In the case where loads to be subjected to air conditioning areinformation instruments as in such a data center, there are featuresdifferent from those in air conditioning control oriented for thegeneral building, such that most of the loads are sensible heat loads,that setting temperature/humidity just need to be within fixed ranges,and that ventilation for preventing an increase of a CO2 concentrationis unnecessary since CO2 is not generated in the loads.

Accordingly, there is a technology for performing air conditioning insuch a manner that the data center is composed to be partitioned intotwo spaces, which are an air supply-side space (cold area) to serversand an air discharge-side space (hot area) therefrom, that returned airfrom an inside of the server room is taken in and subjected totemperature control, and that the air is circulated so as to be suppliedagain into such a room inside.

With such a configuration, a temperature gradient in an area of the roominside is reduced, and in addition, variations of an air supplytemperature are reduced, whereby air conditioning control with a highenergy-saving effect and good efficiency can be performed.

CITATION LIST Patent Literature [PTL 1]

Japanese Patent No. 4503083

SUMMARY OF INVENTION Technical Problem

However, even in the case of performing the air conditioning whiletaking in and circulating the returned air from the server room asmentioned above, outside air with high absolute humidity sometimesenters the room inside from a gap during an operation of the servers,and vapor is sometimes generated from expiration of a person since theperson temporarily stays in the room inside, whereby absolute humidityof the server room to be subjected to the air conditioning controlsometimes rises.

The present invention has been made in consideration of theabove-described circumstances. It is an object of the present inventionto provide a server room managing air conditioning system that controlssuch a control target inside of the server room to keep appropriatehumidity in the event of executing the air conditioning control byperforming the air control for the returned air in the inside of theserver room and by circulating the air so that the air can be suppliedagain into the room inside.

Solution to Problem

In accordance with embodiments for achieving the foregoing object, aserver room managing air conditioning system includes: a first coil; asecond coil; and an air supply fan. The first coil adjusts returned airof a server room to a predetermined temperature value lower than asupplied air temperature target value and dehumidifies the returned air.The second coil is installed in a same area as an area of the firstcoil, and adjusts the returned air of the server room to a predeterminedtemperature value higher than the supplied air temperature target valueso that the supplied air temperature target value and a supplied airhumidity target value can be achieved when the returned air is mixedwith air adjusted by the first coil. The air supply fan mixes thereturned air adjusted by the first coil and the returned air adjusted bythe second coil with each other and supplies the mixed returned air asthe supplied air to the server room.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is an overall view showing a configuration of an air conditioningsystem according to a first embodiment.

FIG. 2 is an explanatory view showing configurations of a cooling coilgroup and outdoor units in the air conditioning system according to thefirst embodiment.

FIG. 3 is an air diagram for classifying states of outside air in eventsof using air conditioning systems according to first to fourthembodiments.

FIG. 4 is a graph showing a relationship between returned airtemperature and supplied air temperature in a case where airconditioning is performed in an all circulation mode in a conventionalair conditioning system.

FIG. 5 is a graph showing a relationship between the returned airtemperature and the supplied air temperature in a case where the airconditioning is performed in the all circulation mode in theconventional air conditioning system and outside air enters the same.

FIG. 6 is a graph showing a relationship between the returned airtemperature and the supplied air temperature in a case where the airconditioning is performed by humidity control and temperature control inthe air conditioning systems according to the first to fourthembodiments.

FIG. 7 is an explanatory view showing configurations of a cooling coilgroup and outdoor units in the air conditioning system according to thesecond embodiment.

FIG. 8 is a block diagram showing a control device of the airconditioning system according to the second embodiment.

FIG. 9 is a graph when the air conditioning system according to thesecond embodiment operates: FIG. 9( a) shows a change of a supplied airabsolute humidity value; FIG. 9( b) shows a change of a supplied airtemperature value; and FIG. 9( c) shows an ON/OFF switching state ofhumidity control.

FIG. 10 is a block diagram showing a configuration of a control deviceof the air conditioning system according to the third embodiment.

FIG. 11 is a graph when the air conditioning system according to thethird embodiment operates: FIG. 11( a) shows a change of a supplied airabsolute humidity value; and FIG. 11( b) shows a change of a suppliedair temperature value.

FIG. 12 is a block diagram showing a configuration of a control deviceof the air conditioning system according to the fourth embodiment.

DESCRIPTION OF EMBODIMENTS First Embodiment

(Configuration of Server Room Managing Air Conditioning System accordingto First Embodiment)

A description is made of a configuration of a server room managing airconditioning system 1A according to a first embodiment of the presentinvention with reference to FIG. 1.

The air conditioning system 1A according to this embodiment performs airconditioning for a server room 10 of a data center or the like. Aninside of the server room 10 is separated into a cold area 12 as a firstspace and a hot area 13 as a second space, and a server rack 11, inwhich a plurality of servers (not shown) are housed, is installedbetween the cold area 12 and the hot area 13.

Then, by operations of fans (not shown) in the servers housed in thisserver rack 11, as shown by arrows a, cold air supplied from an indoorunit 20 to the cold area 12 is sucked into the servers of the serverrack 11, and airflow is generated so that the air supplied to theservers can be flown out, to the hot area 13, as returned air heated byheat generation of the servers. Then, in the servers, heat generatedtherein is cooled by the cold air sucked thereinto, and the serversbecome normally operable.

The air conditioning system 1A includes: the indoor unit 20; and anoutdoor unit group 40.

The indoor unit 20 includes: a returned air introduction area 20Aconnected to the hot area 13 of the server room 10; and a supplied aircooling area 20B connected to the cold area 12 of the server room 10, inwhich a discharging damper 21 is installed in the returned airintroduction area 20A, a returned air introducing damper 22 is installedbetween the returned air introduction area 20A and the supplied aircooling area 20B, and in the supplied air cooling area 20B, there areinstalled an outside air introducing damper 23, a cooling coil group 24as a cold air generation device, a humidifier 25, and an air supply fan26.

The discharging damper 21 adjusts, by an opening degree thereof, anamount of returned air that flows from the hot area 13 of the serverroom 10 into the returned air introduction area 20A and is discharged tothe outside.

The returned air introducing damper 22 adjusts, by an opening degreethereof, a volume of the returned air introduced from the returned airintroduction area 20A to the supplied air cooling area 20B.

The outside air introducing damper 23 adjusts, by an opening degreethereof, a volume of the outside air introduced from the outside intothe supplied air cooling area 20B.

The cooling coil group 24 is composed of a plurality of cooling coils.According to needs, the cooling coil group 24 cools the outside air,which is introduced thereinto when the outside air introducing damper 23is turned to an open state, and the returned air introduced thereintofrom the returned air introduction area 20A when the returned airintroducing damper 22 is turned ton an open state, thereby generatingthe cold air.

According to needs, the humidifier 25 humidifies the outside air and thereturned air, which are introduced thereinto.

The air supply fan 26 flows the cold air, which is generated by beingcooled by the cooling coil group 24 according to needs and by beinghumidified by the humidifier 25 according to needs, as supplied air intothe cold area 12 in the server room 10.

Moreover, in the returned air introduction area 20A, a returned airthermometer 31, which measures temperature of the returned air flownthereinto from the hot area 13, is installed. On the outside of theindoor unit 20, there are installed: an outside air thermometer 32 thatmeasures temperature of the outside air; and an outside air hygrometer33 that measures humidity of the outside air. Downstream of the airsupply fan 26 in the supplied air cooling area 20B, there are installed:a supplied air thermometer 34 that measures temperature of the suppliedair flown into the cold area 12 of the server room 10; and a suppliedair hygrometer 35 that measures humidity of the supplied air thus flownthereinto.

The outside unit group 40 is composed of a plurality of outside units.The plurality of outside units are individually connected to theplurality of cooling coils of the cooling coil group 24, and supplythereto a refrigerant for use in the event of generating the cold air inthe respective cooling coils.

A description is made of detailed configurations of the cooling coilgroup 24 and the outside unit 40 with reference to FIG. 2. In thisembodiment, the cooling coil group 24 is composed of four cooling coils24A to 24D, the outside unit group 40 is composed of four outside units40A to 40D, and the cooling coils and the outside units are connected toeach other by ducts in a one-to-one relationship. The cooling coils 24Ato 24D are installed in the supplied air cooling area 20B. Note that,suitably, the cooling coils 24A to 24D are installed so as not tolongitudinally overlap one another in a direction of 90 degrees withrespect to a flowing direction of the taken-in returned air; however, anangle of the direction concerned is not limited to 90 degrees.

(Operations of Server Room Managing Air Conditioning System according toFirst Embodiment)

Next, a description is made of operations of the server room managingair conditioning system 1A according to this embodiment.

For the purpose of appropriately cooling the servers installed in theserver rack 11, the air conditioning system 1A in this embodiment isoperated: (1) so that the cold air (supplied air supplied from theindoor unit 20 to the server room 10) sucked by the fans in the serverscan satisfy predetermined conditions; and (2) so that the fans in theservers can surely suck the cold air in the cold area and blow out thecold air to the hot area.

Between these, the conditions for the air supply in (1) are determinedin response to a request from the installed servers. In this embodiment,conditions, where temperature ranges from 18 to 27° C., absolutehumidity ranges from 0.0056 to 0.0107 kg/kg, and relative humidity is60% or less, are set in conformity with regulations of ASHRAE (AmericanSociety of Heating, Refrigerating and Air-Conditioning Engineers) orwith regulations similar thereto.

In the case where a supplied air temperature target range and a suppliedair humidity target range are set as described above, a state of theoutside air at present is determined depending on to which region on anair diagram divided as shown in FIG. 3 the outside air concernedapplies. The air diagram refers to a diagram that makes it possible tounderstand thereon a state of humidified air based on the temperature,the absolute/relative humidity, enthalpy, and the like.

In the air diagram of FIG. 3, a state of air with relative humidity of100% (saturated state) or less is divided into regions I to V, whichrepresent five air state ranges to be shown below, based on valuesindicated by the above-mentioned supplied air temperature target rangeand the supplied air humidity target range, and on an upper limit valueand lower limit value of enthalpy corresponding to an air state within arange that applies to the supplied air temperature target range and thesupplied air humidity target range. In this embodiment, it is definedthat such an enthalpy upper limit value corresponding to theabove-mentioned supplied air temperature target range and supplied airhumidity target range is 50 kJ/kg (DA), and that such an enthalpy lowerlimit value corresponding thereto is 35 kJ/kg (DA).

Region I (Fist Air State Range):

The region I is the supplied air temperature target range, and thesupplied air absolute humidity range taken as the target, and a rangesimilar to the supplied air relative humidity range, that is, a rangethat satisfies the following Expression (1) on the air diagram.

[Math. 1]

(temperature: 18° C. or more to 27° C. or less)

∩(absolute humidity: 0.0056 kg/kg (DA) or more to 0.0107 kg/kg(DA) orless)

∩(relative humidity: 60% or less)  Expression (1)

Region II (Second Air State Range):

The region II is a range less than a lower limit value of the suppliedair absolute humidity range taken as the target, and a range less thanthe enthalpy lower limit value in the range taken as the target, thatis, a range that satisfies the following Expression (2) on the airdiagram.

[Math. 2]

(absolute humidity: less than 0.0056 kg/kg(DA))

∩(relative enthalpy: less than 35 kJ/kg(DA))  Expression (2)

Region III (Third Air State Range):

The region III is a range within the supplied air absolute humiditytaken as the target, and a range less than the lower limit value of thesupplied air temperature range taken as the target or equal to or morethan the upper limit value of the supplied air relative humidity takenas the target, that is, a range that satisfies the following Expression(3) on the air diagram.

[Math. 3]

(absolute humidity: 0.0056 kg/kg(DA) or more to 0.0107 kg/kg(DA) orless)

∩{(temperature: less than 18° C.)∪(relative humidity: 60% ormore)  Expression (3)

Region IV (Fourth Air State Range):

The region IV is a range within an enthalpy range corresponding to theranges of the supplied air temperature and the supplied air humidity,which are taken as the targets, and a range less than the lower limitvalue of the supplied air absolute humidity range taken as the target orexceeding the upper limit value of the supplied air temperature rangetaken as the target, that is, a range that satisfies the followingExpression (4) on the air diagram.

[Math. 4]

(relative enthalpy: 35 kJ/kg(DA) or more to 50 kJ/kg(DA) or less)

∩{(absolute humidity: less than 0.0056 kg/kg(DA))∪(temperature:exceeding 27° C.)  Expression (4)

Region V (Fifth Air State Range):

The region V is a range other than the above-described regions I to IV.

When it is determined that the state of the outside air at presentapplies to any of these regions I to IV, air conditioning controlcontents can be set as follows for each of the regions. The settingcontents are decided on the assumption that subjects of the airconditioning control are sensible heat loads by heat generated from theservers in the server room 10, and latent heat loads by expiration ofpersons, and the like are not generated, and that a returned airhumidity vale is the same as a supplied air humidity measurement valuemeasured by the supplied air hygrometer 35.

Air Conditioning Control Contents in Case where Outside Air StateApplies to Region I: When the state of the outside air at present iswithin the region I, the state concerned applies to the above-mentionedsupplied air temperature target range and supplied air humidity targetrange, and it is possible to directly use the outside air as thesupplied air. Therefore, the discharging damper 21 is fully opened, thereturned air introducing damper 22 is closed, and the outside airintroducing damper 23 is fully opened, whereby the control contents aredecided so that an outside air introduction ratio can be 100%. Moreover,at this time, humidifying treatment by the humidifier 25 and coolingtreatment for mixed air by the cooling coil group 24 are not performed.

Air Conditioning Control Contents in Case where Outside Air StateApplies to Region II: When the state of the outside air at present iswithin the region II, the control contents are decided so thattemperature of the outside air can be raised by mixing the returned airwith the outside air and that the outside air can be humidified thereby.Specifically, the control contents are decided so that the openingdegrees of the discharging damper 21, the returned air introducingdamper 22 and the outside air introducing damper 23 can be adjustedbetween 0 and 100% in response to the outside air introduction ratio,and that a necessary amount of humidification can be performed by thehumidifier 25.

At this time, a target value a of the outside air introduction ratio isadjusted by an outside air temperature measurement value and a returnedair temperature measurement value so that air after such mixing canreach a supplied air temperature target value preset within the suppliedair temperature target range and the supplied air humidity target range.

When an outside air absolute humidity measurement value Xo, a returnedair absolute humidity measurement value Xr and the outside airintroduction ratio target value α are used, then an absolute humidityvalue X of the air in which the outside air introduction ratio isadjusted and the outside air and the returned air are mixed with eachother as described above is represented as in the following Expression(5).

[Math. 5]

X=Xo×α+Xr×(1−α)  Expression (5)

Therefore, in order to turn the mixed air into the supplied air in thetarget temperature/humidity state, humidification by an amount of Xs0−Xas a difference thereof from a supplied air absolute humidity targetvalue Xs0 is necessary. When a supplied air flow rate Fs is used, anecessary amount of the humidification for increasing a humidity valueas this difference is represented as Fsx (Xs0−X), and control contentsof a valve (not shown) for controlling a quantity of water of thehumidifier are decided so that this necessary amount of humidificationcan be supplied. At this time, the cooling treatment for the mixed airby the cooling coil group 24 is not performed.

Note that, though the necessary amount of humidification in the event ofperforming the humidification after the mixing of the outside air andthe returned air is decided as described above, it is also possible tomake it unnecessary to perform the humidification after the mixingconcerned in such a manner that the returned air is humidified inadvance so as to achieve the absolute humidity target value of{Xr+(X−Xs0/(1−α).

In this case, the outside air introduction ratio target value α isrepresented by the following Expression (6) where the outside airtemperature measurement value is To, the returned air temperature valueafter the humidification is Tr2, and the supplied air temperature targetvalue is Ts0.

[Math. 6]

α=(Tr2−Ts0)/(Tr2−To)×100(%)  Expression (6)

Air Conditioning Control Contents in Case where Outside Air StateApplies to Region III:

When the state of the outside air at present is within the region III,the control contents are decided so that the temperature of the outsideair can be raised by missing the returned air with the outside air.Specifically, the control contents are decided so that the openingdegrees of the discharging damper 21, the returned air introducingdamper 22 and the outside air introducing damper 23 can be adjustedbetween 0 and 100% in response to the outside air introduction ratio.

In this case, the outside air introduction ratio target value α isrepresented by the following Expression (7) where the outside airtemperature measurement value is To, the returned air temperaturemeasurement value is Tr, and the supplied air temperature target valueis Ts0.

[Math. 7]

α=(Tr−Ts0)/(Tr−To)×100(%)  Expression (7)

At this time, the humidifying treatment by the humidifier 25 and thecooling treatment for the mixed air by the cooling coil group 24 are notperformed.

Air Conditioning Control Contents in Case where Outside Air StateApplies to Region IV:

When the state of the outside air at present is within the region IV,the control contents are decided so as to perform the humidification forthe outside air. Specifically, the discharging damper 21 is fullyopened, the returned air introducing damper 22 is closed, and theoutside air introducing damper 23 is fully opened, whereby the controlcontents are decided so that the outside air introduction ratio can beset at 100%, and that the necessary amount of humidification can beperformed by the humidifier 25.

In this case, when the outside air absolute humidity measurement valueis Xo, and the supplied air humidity target value is Xs0, then thenecessary amount of humidification is Xs0−Xo. At this time, the outsideair temperature drops from To to T following the humidification. In thecase where the supplied air temperature target value Ts0 is lower thanT, the control is performed so that the cooling treatment can beperformed by the cooling coil group 24 so that the outside air can reachthe supplied air temperature target value.

Air Conditioning Control Contents in Case where Outside Air StateApplies to Region V:

When the state of the outside air at present is within the region V, thecontrol contents are decided so as to cool the returned air.Specifically, the discharging damper 21 is closed, the returned airintroducing damper 22 is fully opened, and the outside air introducingdamper 23 is closed, whereby the control contents are decided so thatthe outside air introduction ratio can be set at 0%, and thatcooling/dehumidification treatment can be performed by the cooling coilgroup 24. At this time, the humidification treatment by the humidifier25 is not performed.

When the air conditioning control contents are set as mentioned above,then based on these, the control is performed for the opening degrees ofthe discharging damper 21, the returned air introducing damper 22 andthe outside air introducing damper 23, the control amounts of thehumidifier 25 and the cooling coil group 24, and the number ofrevolutions of the air supply fan 26, the air supply is controlled atthe supplied air temperature value and the supplied air humidity valuewithin the target ranges, and appropriate air conditioning is performed.

Among such types of the air conditioning control as mentioned above, inthe event where the state of the outside air at present is determined tobe within the range of the region V, and the outside air is notintroduced but the supplied air is generated entirely by the returnedair, whereby the air conditioning for the server room 10 is performed,(hereinafter, referred to as an “all circulation mode”), the returnedair (RA) in the hot area 13 of the server room 10 is introduced into thereturned air introduction area 20A, and is taken into the supplied aircooling area 20B in such a manner that the returned air introducingdamper 22 is turned to the open state. Then, the returned air is cooledby the cooling coil group 24 and is humidified by the humidifier 25according to needs, and is supplied as the supplied air (SA) by thecooling fan 26 to the cold area 12 of the server room 10.

At this time, in the server room 10, the latent heat loads are notgenerated though the sensible heat loads are generated. Accordingly, asshown in FIG. 4, the returned air (RA) from the server room 10 and thesupplied air (SA) to the server room 10 are the same in absolutehumidity value and different from each other only in temperature value.

However, in actual, the absolute humidity of the server room as the airconditioning control subject sometimes rises owing to such unexpectedevents that outside air with high humidity enters from the outside airintroducing damper 23, gaps of the cold area 12 and the hot area 13, andthe like, and that a person temporarily stays in the room inside tothereby generate vapor from expiration thereof.

In this case, as shown in FIG. 5, returned air (RA′) with humidityhigher than in the supplied air (SA) supplied to the server room 10 isacquired in the indoor unit 20, and supplied air (SA′) generated by thisreturned air also becomes air with high humidity under the allcirculation mode.

In order to prevent the humidity of the returned air from the serverroom 10 and the humidity of the supplied air to the server 10 fromgradually rising and going out of the appropriate supplied air humiditytarget range by the fact that such a state is repeated, an amount ofrise of the absolute humidity value in the server room 10, which mayrise by the entrance of the outside air with high humidity from the gapsand the like, such temporal entrance of an administrator into the room,and the like, is estimated in advance. Then, in response to this, thecooling coils 24A to 24D of the cooling coil group 24 installed in thesupplied air cooling area 20B are set separately for those to beoperated for adjusting the humidity and for those to be operated foradjusting the temperature.

In this embodiment, in the cooling coil group 24 shown in FIG. 2, thecooling coil 24A is set so as to operate as a first coil for adjustingthe humidity, and prepares supplied air (SA1) in which the returned air(RA′) with the raised humidity, the returned air (RA′) being taken infrom the returned air introduction area 20A, is cooled down totemperature that is lower than the supplied air temperature target value(SA) as shown in FIG. 6 and enables the humidification. The outdoor unit40A supplies a refrigerant of temperature and amount for performing airconditioning to lower the temperature in the cooling coil 24A from thetemperature of the returned air (RA′) to the temperature of the suppliedair (SA1).

Moreover, in the cooling coil group 24, three cooling coils 24B to 24Dare set so as to operate as second coils for adjusting the temperature,and prepare supplied air (SA2) in which the returned air (RA′) taken infrom the returned air introduction area 20A is cooled down totemperature higher than the supplied air temperature target value (SA)as shown in FIG. 6. The temperature of this supplied air (SA2) has avalue decided so that the supplied air temperature target value and thesupplied air humidity target value can be achieved at the time of mixingthe air prepared by the cooling coil 24A and the air prepared by thecooling coils 24B to 24D with each other. The outdoor units 40B to 40Dsupply the refrigerant of the temperature and the amount for performingthe air conditioning to lower the temperature in the cooling coils 24Bto 24D from the temperature of the returned air (RA′) to the temperatureof the supplied air (SA2). The humidity adjustment is not performed inthese cooling coils 24B to 24D.

When the humidity adjustment and the temperature adjustment for thetaken-in returned air are performed for the flow of the returned air bythe cooling coils 24A to 24D as described above, the supplied airalready adjusted by the respective cooling coils 24A to 24D is naturallymixed together in the supplied air cooling area 20B, and the suppliedair (SA) with the supplied air temperature target value and the suppliedair humidity target value is obtained, and is then supplied to the coldarea 12 of the server room 10 by the air supply fan 26.

In accordance with this embodiment described above, in the event wherethe air conditioning control for the server room is performed in the allcirculation mode, in the case where the amount of rise of the absolutehumidity in the server room owing to the unexpected events can beestimated in advance, the cooling coil for the humidity control and thecooling coils for the temperature control, in which the number and thecontrol amounts are decided in response to such estimation, areinstalled in the supplied air cooling area as the same space, wherebythe supplied air with the target temperature value and the targethumidity value can be supplied to the server room.

Second Embodiment

(Configuration of Server Room Managing Air Conditioning System Accordingto Second Embodiment)

A description is made of a configuration of a server room managing airconditioning system 1B according to a second embodiment of the presentinvention with reference to FIG. 7.

The air conditioning system 1B according to this embodiment has asimilar configuration to that of the air conditioning system 1Aaccording to the first embodiment except that a control device 50B isprovided as shown in FIG. 7, and accordingly, a detailed description ofdevices having the same functions is omitted.

As shown in FIG. 8, the control device 50B includes: a threshold valueinformation storage unit 501; a supplied air humidity measurement valueacquisition unit 502; a determination unit 503; and a control signaltransmission unit 504.

The threshold value information storage unit 501 stores information onan upper limit threshold value of the supplied air humidity measurementvalue for determining whether or not to execute the humidity control(for example, the upper limit threshold value is “absolute humidity:0.0107 kg/kg” as an upper limit value of the humidity range of theregion I) and on a lower limit threshold value therefor (for example,the lower limit threshold value is “absolute humidity: 0.0056 kg/kg” asa lower limit value of the humidity range of the region I).

The supplied air humidity measurement value acquisition unit 502acquires the supplied air humidity measurement value measured by thesupplied air hygrometer 35.

The determination unit 503 determines whether or not the supplied airhumidity measurement value acquired by the supplied air humiditymeasurement value acquisition unit 502 is within a range between theupper limit threshold value and the lower limit threshold value, whichare stored in the threshold value information storage unit 501.

In the case where it is determined in the determination unit 503 thatthe supplied air humidity measurement value exceeds the upper limitthreshold value, the control signal transmission unit 504 turns, to anON state, the cooling coil 24A set as the first coil, transmits acontrol signal for starting an operation to the outdoor unit 40Acorresponding thereto, and allows the outdoor unit 40A concerned toexecute the humidity control. Moreover, in the case where the suppliedair humidity measurement value thus acquired falls down below the presetlower limit threshold value, the control signal transmission unit 504turns, to an OFF state, the cooling coil 24A set as the first coil,transmits a control signal for stopping the operation to the outdoorunit 40A corresponding thereto, and allows the outdoor unit 40Aconcerned to stop the humidity control.

(Operations of Server Room Managing Air Conditioning System According toSecond Embodiment)

Next, a description is made of operations of the server room managingair conditioning system 1B according to this embodiment.

When the air conditioning system 1B operates in this embodiment, thesupplied air humidity measurement value measured by the supplied airhygrometer 35 is acquired in the supplied air humidity measurement valueacquisition unit 502 of the control device 50B.

Next, in the determination unit 503, it is determined whether or not thesupplied air humidity measurement value acquired by the supplied airhumidity measurement value acquisition unit 502 is within the rangebetween the upper limit threshold value and the lower limit thresholdvalue, which are stored in the threshold value information storage unit501. As a result of the determination, in the case where it isdetermined that the supplied air humidity measurement value thusacquired exceeds the upper limit threshold value prestored in thethreshold value information storage unit, it is decided that the coolingcoil 24A be turned to the ON state, and in the case where it isdetermined that the supplied air humidity measurement value thusacquired falls down below the lower limit threshold value thus stored,it is decided that the cooling coil 24A be turned to the OFF state.

When it is decided in the determination unit 503 that the cooling coil24A be turned to the ON state, the control signal for starting theoperation of the outdoor unit 40A corresponding to the cooling coil 24Ais transmitted from the control signal transmission unit 504 to theoutdoor unit 40A, and when it is decided in the determination unit 503that the cooling coil 24A be turned to the OFF state, the control signalfor stopping the operation of the outdoor unit 40A is transmitted fromthe control signal transmission unit 504 to the outdoor unit 40A.

FIG. 9 shows a relationship among: (a) a change of the supplied airabsolute humidity value; (b) a change of the supplied air temperaturevalue; and (c) an ON/OFF switching state of the humidity control, whenthe operation of the outdoor unit 40A is controlled as described above,and ON/OFF of the cooling coil 24A are thereby controlled.

As shown in FIG. 9, first, during a period (period from time t0 to timet1) from when the measurement is started until when the supplied airhumidity measurement value reaches the upper limit threshold value, theabsolute humidity of the server room 10 is within the appropriate rangebetween the upper limit threshold value and the lower limit thresholdvalue, the humidity control is in the OFF state, and the operation ofthe outdoor unit 40A is stopped by the control of the control device 50.At this time, with regard to the air conditioning control for thereturned air acquired from the server room 10, only the temperaturecontrol is executed by the cooling coils 24B to 24D as the second coilsbased on the supplied air temperature measurement value acquired fromthe supplied air thermometer 34, and supplied air at temperature (Tsa1)within the target temperature range (for example, “temperature: 18° C.or more to 27° C. or less” as the temperature range of the region I) isgenerated.

Next, when the supplied air humidity measurement value rises and reachesthe upper limit threshold value owing to the entrance of the outside airfrom the gap, and the like during the air conditioning control (at thetime t1), then it is decided by the control device 50 that the humiditycontrol be shifted to the ON state, and the control signal for operatingthe outdoor unit 40A is transmitted thereto. Then, the outdoor unit 40Ais operated by this control signal, and the supply of the refrigerant ofpredetermined temperature and amount to the cooling coil 24A is started.

After the humidity control is shifted to the ON state, during a period(period from time t1 to time t2) until when the supplied air humiditymeasurement value reaches the lower limit threshold value, the humiditycontrol is continuously executed, and in a similar way to the casedescribed in the first embodiment, the outdoor units 40A to 40D arecontrolled by the control device 50 so that supplied air at lowertemperature (Tsa1′) than the supplied air temperature target value canbe prepared in the cooling coil 24A, and that supplied air at highertemperature (Tsa2) than the supplied air temperature target value can beprepared in the cooling coils 24B to 24D.

The humidity control is started as described above, whereby the suppliedair humidity measurement value starts to drop. Moreover, since thesupplied air prepared in the cooling coil 24A is of the low temperature(Tsa1′), the temperature of the supplied air supplied to the server roomdrops within the target temperature range by being affected by thissupplied air of the low temperature. Specifically, the cooling coil 24Athat performs the humidity control is one, meanwhile, the cooling coils24B to 24D which perform the temperature control are three, and thetemperature (Tsa) of the supplied air supplied to the server room 10 isrepresented by the following Expression (8).

[Math. 8]

Tsa=0.25×Tsa1′+0.75×Tsa2  (8)

Next, when the supplied air humidity measurement value reaches the lowerlimit threshold value (time t2) because the humidity control is executedcontinuously, it is decided by the control device 50 that the humiditycontrol be shifted to the OFF state, and the control signal for stoppingthe operation of the outdoor unit 40A is transmitted thereto. Then, theoperation of the outdoor unit 40A is stopped.

Thereafter, when the supplied air humidity measurement value reaches theupper limit threshold value again (time t3) owing to the entrance of theoutside air, and the like, then it is decided by the control device 50that the humidity control be shifted to the ON state, and similartreatment is repeated.

In accordance with this embodiment described above, based on thesupplied air temperature measurement value and supplied air humiditymeasurement value of the server room as the air conditioning controlsubject, cooling volumes for the returned air by the respective coolingcoils are decided so that the supplied air temperature and the suppliedair humidity can remain within the target ranges. Therefore, variationsof a humidity amount in the server room, which is increased more thanexpected, can also be coped with, and the supplied air with the targettemperature value and the target humidity value can be supplied to theserver room with higher accuracy.

Third Embodiment

(Configuration of Server Room Managing Air Conditioning System Accordingto Second Embodiment)

A server room managing air conditioning system 10 according to a thirdembodiment of the present invention has a similar configuration to thatof the air conditioning system 1A according to the first embodimentexcept that a control device 50C is provided as shown in FIG. 7, andaccordingly, a detailed description of devices having the same functionsis omitted.

The control device 50C performs PID control for the cooling coil group24. As shown in FIG. 10, the control device 50C includes: a humiditycontrol table storage unit 505; a supplied air humidity measurementvalue acquisition unit 502; a difference calculation unit 506; a coolingvolume acquisition unit 507; a humidity PID control unit 508; atemperature control table storage unit 509; a supplied air temperaturemeasurement value acquisition unit 510; a difference calculation unit511; a cooling volume acquisition unit 512; and a temperature PIDcontrol unit 513.

The humidity control table storage unit 505 prestores a humidity controltable indicating the cooling volumes for the returned air in the coolingcoils for the humidity control for each difference between the suppliedair humidity target value and the supplied air humidity measurementvalue.

The supplied air humidity measurement value acquisition unit 502acquires the supplied air humidity measurement value measured by thesupplied air hygrometer 35.

The difference calculation unit 506 calculates the difference betweenthe preset supplied air humidity target value and the supplied airhumidity measurement value acquired by the supplied air humiditymeasurement value acquisition unit 502.

The cooling volume acquisition unit 507 acquires the cooling volume forthe returned air for humidity control, which corresponds to thedifference calculated by the difference calculation unit 506, based onthe humidity control table prestored in the humidity control tablestorage unit 505.

The humidity PID control unit 508 decides the temperature and amount ofthe refrigerant necessary for the humidity control based on the coolingvolume for the returned air, which is for the humidity control and isacquired by the cooling volume acquisition unit 507, and therebycontrols the operation of the outdoor unit 40A.

The temperature control table storage unit 509 prestores a temperaturecontrol table indicating the cooling volumes for the returned air in thecooling coils for the temperature control for each difference betweenthe supplied air temperature target value and the supplied airtemperature measurement value.

The supplied air temperature measurement value acquisition unit 510acquires the supplied air temperature measurement value measured by thesupplied air thermometer 34.

The difference calculation unit 511 calculates the difference betweenthe preset supplied air temperature target value and the supplied airtemperature measurement value acquired by the supplied air temperaturemeasurement value acquisition unit 510.

The cooling volume acquisition unit 512 acquires the cooling volume forthe returned air for temperature control, which corresponds to thedifference calculated by the difference calculation unit 511, based onthe temperature control table prestored in the temperature control tablestorage unit 509.

The temperature PID control unit 513 decides the temperature and amountof the refrigerant necessary for the temperature control based on thecooling volume for the returned air, which is for the temperaturecontrol and is acquired by the cooling volume acquisition unit 512, andthereby controls the operations of the outdoor units 40A to 40D.

(Operations of Server Room Managing Air Conditioning System According toThird Embodiment)

Next, a description is made of operations of the server room managingair conditioning system 1C according to this embodiment.

In this embodiment, when the air conditioning system 1C operates, thecooling coil 24A and the outdoor unit 40A are always set in the ONstate.

Then, the supplied air humidity measurement value measured by thesupplied air hygrometer 35 is acquired in the supplied air humiditymeasurement value acquisition unit 502 of the control device 50C.

Next, in the difference calculation unit 506, the difference between thesupplied air humidity measurement value acquired by the supplied airhumidity measurement value acquisition unit 502 and the supplied airhumidity target value thus prestored is calculated.

Next, in the cooling volume acquisition unit 507, the cooling volume forthe returned air for the humidity control, which corresponds to thedifference calculated in the difference calculation unit 506, isacquired based on the humidity control table prestored in the humiditycontrol table storage unit 505.

Next, in the humidity PID control unit 508, the temperature and amountof the refrigerant necessary for the humidity control are decided basedon the cooling volume for the returned air, which is for the humiditycontrol and is acquired by the cooling volume acquisition unit 507,whereby the operation of the outdoor unit 40A is controlled. Here, withregard to the humidity control, the temperature and amount of therefrigerant are decided so that the supplied air at the lowertemperature (Tsa1′) than the supplied air temperature target value canbe prepared in a similar way to the case described in the firstembodiment.

Meanwhile, in the supplied air temperature measurement value acquisitionunit 510, the supplied air temperature measurement value measured in thesupplied air thermometer 34 is acquired.

Next, in the difference calculation unit 511, the difference between thesupplied air temperature measurement value acquired by the supplied airtemperature measurement value acquisition unit 510 and the supplied airtemperature target value thus prestored is calculated.

Next, in the cooling volume acquisition unit 512, the cooling volume forthe returned air for the temperature control, which corresponds to thedifference calculated in the difference calculation unit 511, isacquired based on the temperature control table prestored in thetemperature control table storage unit 509.

Next, in the temperature PID control unit 513, the temperature andamount of the refrigerant necessary for the temperature control aredecided based on the cooling volume for the returned air, which is forthe temperature control and is acquired by the cooling volumeacquisition unit 512, whereby the operations of the outdoor units 40A to40D are controlled. Here, with regard to the temperature control, thetemperature and amount of the refrigerant are decided so that thesupplied air at the higher temperature (Tsa2) than the supplied airtemperature target value can be prepared in a similar way to the casedescribed in the first embodiment.

Among them, to the information on the cooling volume for the returnedair for the temperature control of the outdoor unit 40A, there is addedthe above-mentioned information on the cooling volume for the returnedair for the humidity control, and the temperature and amount of therefrigerant are decided.

FIG. 11 shows a relationship among: (a) a change of the supplied airabsolute humidity value; (b) a change of the supplied air temperaturevalue; and (c) an ON/OFF switching state of the humidity control, whenthe operation of the outdoor unit 40A is controlled as described above.

In this embodiment, the control is executed, which corresponds to thedifferences between the target values and the supplied air humiditymeasurement value and the supplied air temperature measurement value,both of the measurement values being sequentially acquired by the PIDcontrol. Accordingly, as shown in FIGS. 11( a) and 11(b), both of thesupplied air humidity measurement value and the supplied air temperaturemeasurement value can be maintained in states close to constant stateswithout being largely deviated from the target values.

In accordance with this embodiment described above, based on thesupplied air temperature measurement value and supplied air humiditymeasurement value of the server room as the air conditioning controlsubject, the cooling volumes for the returned air by the respectivecooling coils are decided so that the supplied air temperature and thesupplied air humidity can be maintained in the states close to theconstant states. Therefore, the variations of the humidity amount in theserver room, which is increased more than expected, can also be copedwith sequentially, and the supplied air with the target temperaturevalue and the target humidity value can be supplied to the server roomwith higher accuracy.

Fourth Embodiment

(Configuration of Server Room Managing Air Conditioning System Accordingto Fourth Embodiment)

A server room managing air conditioning system 1D according to a fourthembodiment of the present invention has a similar configuration to thatof the air conditioning system 1A according to the first embodimentexcept that a control device 50D is provided as shown in FIG. 7, andaccordingly, a detailed description of devices having the same functionsis omitted.

The air conditioning system 1D performs PID control for the cooling coilgroup 24. As shown in FIG. 10, the control device 50D includes: ahumidity control table storage unit 505; a supplied air humiditymeasurement value acquisition unit 502; a difference calculation unit506; a cooling volume acquisition unit 507; a humidity PID control unit508; a temperature control table storage unit 509; a supplied airtemperature measurement value acquisition unit 510; a differencecalculation unit 511; a cooling volume acquisition unit 512; atemperature PID control unit 513; switches 514 to 517; and cooling coilsetting control unit 518.

Among them, functions of the humidity control table storage unit 505,the supplied air humidity measurement value acquisition unit 502, thedifference calculation unit 506, the cooling volume acquisition unit507, the temperature control table storage unit 509, the supplied airtemperature measurement value acquisition unit 510, the differencecalculation unit 511 and the cooling volume acquisition unit 512 are thesame as functions of the corresponding units of the control device 50Baccording to the third embodiment, and accordingly, a detaileddescription thereof is omitted.

The humidity PID control unit 508 decides the temperature and amount ofthe refrigerant necessary for the humidity control based on the coolingvolume for the returned air, which is for the humidity control and isacquired by the cooling volume acquisition unit 507, and on controlsetting statuses of the cooling coils 24A to 24D, which are set by thecooling coil setting control unit 518 to be described later, and therebycontrols the operations of the outdoor units 40A to 40D.

The temperature PID control unit 513 decides the temperature and amountof the refrigerant necessary for the temperature control based on thecooling volume for the returned air, which is for the temperaturecontrol and is acquired by the cooling volume acquisition unit 512, andon control setting statuses of the cooling coils 24A to 24D, which areset by the cooling coil setting control unit 518 to be described later,and thereby controls the operations of the outdoor units 40A to 40D.

The switch 514 is turned to the ON state, thereby connecting thehumidity PID control unit 508 and the outdoor unit 40A to each other,and is turned to the OFF state, thereby disconnecting the connectionbetween the PID control unit 508 and the outdoor unit 40A.

The switch 515 is turned to the ON state, thereby connecting thehumidity PID control unit 508 and the outdoor unit 40B to each other,and is turned to the OFF state, thereby disconnecting the connectionbetween the PID control unit 508 and the outdoor unit 40B.

The switch 516 is turned to the ON state, thereby connecting thehumidity PID control unit 508 and the outdoor unit 40C to each other,and is turned to the OFF state, thereby disconnecting the connectionbetween the PID control unit 508 and the outdoor unit 40C.

The switch 517 is turned to the ON state, thereby connecting thehumidity PID control unit 508 and the outdoor unit 40D to each other,and is turned to the OFF state, thereby disconnecting the connectionbetween the PID control unit 508 and the outdoor unit 40D.

The cooling coil setting control unit 518 acquires the measurement valuemeasured by the outside air thermometer 32, the measurement valuemeasured by the outside air thermometer 33, the measurement valuemeasured by the supplied air thermometer 34, the measurement valuemeasured by the supplied air hygrometer 35, a supplied air volume by theair supply fan 26, and load states of the servers housed in the serverrack 11. Based on these pieces of information, the cooling coil settingcontrol unit 518 makes a setting as to whether each of the cooling coils24A to 24D is used for the humidity control or the temperature control.By this setting, the switch 514 is turned to the ON state at the time ofmaking a setting that the cooling coil 24A is to be used for thehumidity control, the switch 515 is turned to the ON state at the timeof making a setting that the cooling coil 24B is to be used for thehumidity control, the switch 516 is turned to the ON state at the timeof making a setting that the cooling coil 24C is to be used for thehumidity control, and the switch 517 is turned to the ON state at thetime of making a setting that the cooling coil 24D is to be used for thehumidity control.

(Operations of Server Room Managing Air Conditioning System According toFourth Embodiment)

Next, a description is made of operations of the server room managingair conditioning system 1D according to this embodiment.

When the operation of the air conditioning system 1D is started in thisembodiment, first, the measurement value measured by the outside airthermometer 32, the measurement value measured by the outside airthermometer 33, the measurement value measured by the supplied airthermometer 34, the measurement value measured by the supplied airhygrometer 35, the supplied air volume by the air supply fan 26, and theload states of the servers housed in the server rack 11 are acquired inthe cooling coil setting control unit 518.

Then, based on these pieces of the acquired information, it is decidedhow many cooling coils in the cooling coil group 24 are to be used forthe humidity control and how many cooling coils therein are to be usedfor the temperature control. In this embodiment, the cooling coil group24 is composed of four cooling coils 24A to 24D, and therefore, thesecooling coils can be allocated as those for use in the humidity controland those for use in the temperature control in a ratio of 1:3 or 2:2. Aselection can be made from: a pattern (3:1) that the cooling coil 24A isused for the humidity control and the cooling coils 24B to 24D are usedfor the temperature control; a pattern (2:2) that the cooling coils 24Aand 24B are used for the humidity control and the cooling coils 24C and24D are used for the temperature control; and a pattern (1:3) that thecooling coil 24A is used for the humidity control and the cooling coils24B to 24D are used for the temperature control. In the event of makingthe selection of the pattern, a pattern in which energy consumption isthe smallest is selected based on a result of a test performed inadvance, whereby an energy saving effect can be enhanced.

When the number of cooling coils for use in the humidity control and thenumber of cooling coils for use in the temperature control are decided,then based on such decision, it is decided which cooling coils are to beused for the humidity control and which cooling coils are to be used forthe temperature control.

At this time, a setting is made so that the cooling coil for use in thehumidity control among the cooling coils 24A to 24D cannot be tiltedtoward a specific cooling coil, whereby a large load owing to thehumidity control can be prevented from being applied only to specificcooing coil and outdoor unit, and an entire lifetime of the coolingcoils 24A to 24D and the outdoor units 40A to 40D can be extended.

Here, by the cooling coil setting control unit 518, the switchcorresponding to the outdoor unit connected to the cooling coil decidedto perform the humidity control is tuned to the ON state, whereby theoutdoor unit concerned is connected to the humidity PID control unit508. In such a way, the information regarding the humidity control istransmitted from the humidity PID control unit 508 to the outdoor unitconcerned.

Moreover, the control setting statuses of the cooling coils 24A to 24D,which are decided by the cooling coil setting control unit 518, are sentout to the humidity PID control unit 508 and the temperature PID controlunit 513.

Meanwhile, in the supplied air humidity measurement value acquisitionunit 502, the difference calculation unit 506 and the cooling volumeacquisition unit 507, similar treatments to those in the case of thecontrol device 50C according to the third embodiment are executed, andin the humidity PID control unit 508, the temperature and amount of therefrigerant necessary for the humidity control are decided based on thecooling volume for the returned air, which is for the humidity controland is acquired by the cooling volume acquisition unit 507, and on thecontrol setting statuses of the cooling coils 24A to 24D, which are sentout from the cooling coil setting control unit 518, whereby the switchis turned to the ON state, and the operation of the outdoor unit 40connected to the humidity PID control unit 508 is controlled.

Moreover, in the supplied air temperature measurement value acquisitionunit 510, the difference calculation unit 511 and the cooling volumeacquisition unit 512, similar treatments to those in the case of thecontrol device 50C according to the third embodiment are executed, andin the humidity PID control unit 513, the temperature and amount of therefrigerant necessary for the temperature control are decided based onthe cooling volume for the returned air, which is for the temperaturecontrol and is acquired by the cooling volume acquisition unit 512, andon the control setting statuses of the cooling coils 24A to 24D, whichare sent out from the cooling coil setting control unit 518, whereby theoperations of the outdoor units 40A to 40D are controlled.

At this time, in the control of the outdoor unit, which corresponds tothe humidity control, the above-mentioned information on the coolingvolume for the returned air for the humidity control is added to theinformation on the cooling volume for the returned air for thetemperature control, and the temperature and amount of the refrigerantare decided.

Moreover, even among the plurality of cooling coils which perform thehumidity control and the temperature control, it is also possible to setdifferent cooling volumes. The supplied air finally mixed after beingcooled by these cooling coils 24A to 24D just needs to attain a balanceas a whole so as to achieve the supplied air humidity target value andthe supplied air temperature target value.

In accordance with this embodiment described above, based on thesupplied air temperature measurement value and supplied air humiditymeasurement value of the server room as the air conditioning controlsubject, the cooling volumes for the returned air by the respectivecooling coils are decided so that the supplied air temperature and thesupplied air humidity can be maintained in the states close to theconstant states. Therefore, the variations of the humidity amount in theserver room, which is increased more than expected, can also be copedwith sequentially, and the supplied air with the target temperaturevalue and the target humidity value can be supplied to the server roomwith high accuracy, and in addition, a higher energy saving effect canbe obtained.

In the above first to third embodiments, the description has been madeof the case where the cooling coil group is connected individually tothe different outdoor units; however, without being limited to this, aconfiguration may be adopted so that the plurality of cooling coils canbe connected to one another, and can be managed as a group.

The description has been made of some embodiments of the presentinvention; however, these embodiments are illustrated as examples, anddo not intend to limit the scope of the invention. It is possible toembody these novel embodiments in other various forms, and for theembodiments, varieties of omissions, substitutions and alterations canbe performed within the scope without departing from the spirit of theinvention. These embodiments and modifications thereof are incorporatedin the scope and spirit of the invention, and in addition, areincorporated in inventions described in the scope of claims and a rangeof equilibrium thereof.

1. A server room managing air conditioning system, which takes inreturned air of a server room as an air conditioning control subject,and supplies, to the server room, supplied air adjusted to a suppliedair temperature target value and a supplied air humidity target value,the air conditioning system comprising: a first coil that adjusts thereturned air of the server room to a predetermined temperature valuelower than the supplied air temperature target value and dehumidifiesthe returned air; a second coil that is installed in a same area as anarea of the first coil, and adjusts the returned air of the server roomto a predetermined temperature value higher than the supplied airtemperature target value so that the supplied air temperature targetvalue and the supplied air humidity target value can be achieved whenthe returned air is mixed with air adjusted by the first coil; and anair supply fan that mixes the returned air adjusted by the first coiland the returned air adjusted by the second coil with each other andsupplies the mixed returned air as the supplied air to the server room.2. The server room managing air conditioning system according to claim1, further comprising: a supplied air thermometer that measures atemperature value of the supplied air supplied to the server room by theair supply fan; a supplied air hygrometer that measures a humidity valueof the supplied air; and a control device that individually decidescontrol amounts for the first coil and the second coil based on thetemperature value measured by the supplied air thermometer and on thehumidity value measured by the supplied air hygrometer.
 3. The serverroom managing air conditioning system according to claim 2, wherein thecontrol device operates the first coil when the humidity value measuredby the supplied air hygrometer becomes higher than a preset thresholdvalue.
 4. The server room managing air conditioning system according toclaim 2, wherein, based on a difference between the humidity valuemeasured by the supplied air hygrometer and the supplied air humiditytarget value, the control device decides the control amount for thefirst coil so that the difference can be eliminated.
 5. The server roommanaging air conditioning system according to any one of claims 1 to 4,wherein at least either of the first coil and the second coil iscomposed of a plurality of coils, and the control device decides anumber of the first coils and a number of the second coils among theplurality of coils based on the humidity value measured by the suppliedair hygrometer, and operates the first coil and the second coil based onthe decided number of first coils and the decided number of secondcoils.